US1826886A - Measuring electric conductivity of fluid - Google Patents

Measuring electric conductivity of fluid Download PDF

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US1826886A
US1826886A US670143A US67014323A US1826886A US 1826886 A US1826886 A US 1826886A US 670143 A US670143 A US 670143A US 67014323 A US67014323 A US 67014323A US 1826886 A US1826886 A US 1826886A
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fluid
electrodes
temperature
electrode
conductivity
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US670143A
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Earl A Keeler
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Brown Instruments Co
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Brown Instr Co
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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N27/00Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
    • G01N27/02Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance
    • G01N27/04Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance by investigating resistance
    • G01N27/06Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance by investigating resistance of a liquid

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  • the invention is characterized by the provisions made for obtaining a mechanical adj ustment of the electric path of flow between the electrodes connected to the measuring instrument, in automatic response to the temperature change in the fluid, and of such character as to maintain the resistanceof said at-h of flow constant when the temperature of the electrolyteor other fluid forming the,
  • the mechanical adjustment of the flow path made in accordance with the present invention may consist in a change in the length, or the shape, or both the length and shape of the flow path between the elec trodes by means of which the conductivity measurement A is efi'ected.
  • this adjustment I employ thermostatic means which are ordinarily immersed in the electrolyte so as to vary with the temperature of the latter, though in some casesthey may be responsive in whole or in part to the temperature of the gas above the electrolytic solution, and which operate in re- .sponse to a change in temperature to correthe length or s'ha of the path of electric flow between the e ectrodes.
  • Flg. 1 is a diagrammatic elevation of one form of my invention. a
  • Fig. 2 is a diagrammatic elevation of a second form of the invention.
  • Fig. 3 is an elevation of a third form of the invention.
  • Fig. 4 Isa view taken at right angles to I Fi 3.
  • A represents'a vessel open at its upper end and containing an electrolytic so lution B, the conductivity of which is measured by means comprising two electrodes C and D.
  • t e electrodes C and D are secured to a support E of insulating material.
  • the electrode 0 may be of any usual or suit able form but the electrode D is in effect a bi-metallic thermostat com osed of strips d and d with a coeflicient 0 thermal ex ansion of the strip (1' greater than that of the strip d, so that the electrode D bends toward and away from the electrode C as the temperature of the solution B decreases and increases, respectively.
  • 1 suitably proportioned and arranged, it is thus possible to cause the electrodes C and D to approach and separate as required to maintain an electric flow path of constant resistance between the electrodes G and D regardless of the temperature changes in the electrolyte.
  • 1 and 2 represents conductors by means of which the electrodes G and D may be connected in circuit with a source of current and an electrical measuring instrument which may be of any suitable type and hence is not illustrated herein.
  • the form of my invention illustrated in Fig. 2 differs from that shown in Fig. 1, in that the electrode D of Fig. 1 is replaced .in Fig. 2 by an electrode DA which is carried at the free outer end of a bi-metallic thermostat in the form of a Briguet spiral, the inner end of which is secured to a stud G carried at the lower end of a post G, the latter being attached at its upper end to the insulation support E.
  • the electrode DA is electrically connected to a post member D mounted m the support E by a flexible conductor D.
  • the strip d having the greatest co eflicient of thermal expansion is the inner strip so that the electrode DA will be moved toward and away from the electrode C as the temperature of the electrolytic solution B falls and rises. With the comparatively small range of movement thus imparted to the electrode DA, the movement of the latter is substantially wholly in the horizontal direction.
  • H represents a metal plug adapted to be screwed into an aperture in the wall of a conduit or receptacle containing an electrolyte or other fluid. the conductivity of which is to be measured.
  • insulating sleeves I and K which surround the terminal portions of electrodes I and K, located at the inner end of the plug.
  • the electrode terminal. portions are connected to suitable binding posts I and K
  • the electrodes I and K are in the form of parallel plate-like bodies, and the shape and effective length of the flow path between them is varied by means of a barrier L of insulating material which is movable in a plane between and parallel to the electrodes.
  • a device for measuring the electric conductivity of a fluid having electrodes immersed in said fluid, an obstruction movable to vary'the path of electrical flow between said electrodes, and thermally responsive means in the fluid for operating the obstruction in accordance with temperature changes of the fluid.

Description

Oct. 13, 1931. E. A. KEELER 1,826,886
MEASURING ELECTRIC CONDUCTIVITY OF FLUID Filed Oct. 22, 1925 INVENTOR 4 E451 Ma [,6
BY fl W ATTORNEY Patented Oct, 13, 1931 fluid varies with its temperature.
UNITED STATES PATENTOFFICE,
EARL A. KEELER, OF PHILADELPHIA, PENNSYLVANIA, ASSIGNOR TO BROWN INSTRU- MENT COMPANY, OF PHILADELPHIA, PENNSYLVANIA, A. CORPORATION OF PENN- BYLVANIA MEASURING ELECTRIC CONDUCTIYI'I'Y OI FLUID Application filed October 82, 1983. Serial No. 670,143.
solution, difliculty has heretofore been ex-;
conductivity of such a In ordinary electrolytic solutions the variation in perienced because the conductivity resulting from a change in tem-" rature amounts to more than 1% per degree of temperature change, and is negatlve n character. Various arrangements have heretofore been devised for obtaining a compensation in the electrical measuring instrument, or in the. circuit connecting it to the electrodes in contact with the electrolyte, for the effect of changes in the temperature of the electrolyte, but such arrangements have not been entirely satisfactory, and the general object of the present invention is to provide an. improved method of, nd means for automatically compensating for the effect of variations in the temperature of a fluid in measuring lts electrical conductivity The invention is characterized by the provisions made for obtaining a mechanical adj ustment of the electric path of flow between the electrodes connected to the measuring instrument, in automatic response to the temperature change in the fluid, and of such character as to maintain the resistanceof said at-h of flow constant when the temperature of the electrolyteor other fluid forming the,
path changes. The mechanical adjustment of the flow path made in accordance with the present invention may consist in a change in the length, or the shape, or both the length and shape of the flow path between the elec trodes by means of which the conductivity measurement A is efi'ected. In a preferred mode of efiecting this adjustment I employ thermostatic means which are ordinarily immersed in the electrolyte so as to vary with the temperature of the latter, though in some casesthey may be responsive in whole or in part to the temperature of the gas above the electrolytic solution, and which operate in re- .sponse to a change in temperature to correthe length or s'ha of the path of electric flow between the e ectrodes.
The various features of novelty which characterize my invention are ointed out with particularity in'the claims annexed to and formmg a part of this specification. For a better understanding of the invention, howover, its advantages and specific ob'ects attained with its use, reference shoul be had to the accompanying drawings and descriptive matter in w ich I have illustrated and described preferred embodiments of my invention.
Of the drawings:
Flg. 1 is a diagrammatic elevation of one form of my invention. a
Fig. 2 is a diagrammatic elevation of a second form of the invention.
Fig. 3 is an elevation of a third form of the invention; and.
Fig. 4 Isa view taken at right angles to I Fi 3.
- in Fig. 1, A represents'a vessel open at its upper end and containing an electrolytic so lution B, the conductivity of which is measured by means comprising two electrodes C and D. As shown, t e electrodes C and D are secured to a support E of insulating material. The electrode 0 may be of any usual or suit able form but the electrode D is in effect a bi-metallic thermostat com osed of strips d and d with a coeflicient 0 thermal ex ansion of the strip (1' greater than that of the strip d, so that the electrode D bends toward and away from the electrode C as the temperature of the solution B decreases and increases, respectively. With the parts shown in Fig. 1 suitably proportioned and arranged, it is thus possible to cause the electrodes C and D to approach and separate as required to maintain an electric flow path of constant resistance between the electrodes G and D regardless of the temperature changes in the electrolyte. 1 and 2 represents conductors by means of which the electrodes G and D may be connected in circuit with a source of current and an electrical measuring instrument which may be of any suitable type and hence is not illustrated herein.
The form of my invention illustrated in Fig. 2 differs from that shown in Fig. 1, in that the electrode D of Fig. 1 is replaced .in Fig. 2 by an electrode DA which is carried at the free outer end of a bi-metallic thermostat in the form of a Briguet spiral, the inner end of which is secured to a stud G carried at the lower end of a post G, the latter being attached at its upper end to the insulation support E. The electrode DA is electrically connected to a post member D mounted m the support E by a flexible conductor D. In the riguet spiral arranged as shown in Fig. 2, the strip d having the greatest co eflicient of thermal expansion is the inner strip so that the electrode DA will be moved toward and away from the electrode C as the temperature of the electrolytic solution B falls and rises. With the comparatively small range of movement thus imparted to the electrode DA, the movement of the latter is substantially wholly in the horizontal direction.
In the form of my invention illustrated in Figs. 3 and 4, H represents a metal plug adapted to be screwed into an aperture in the wall of a conduit or receptacle containing an electrolyte or other fluid. the conductivity of which is to be measured. Mounted in passages extending through the plug H are insulating sleeves I and K which surround the terminal portions of electrodes I and K, located at the inner end of the plug. At the outer end of the plug, the electrode terminal. portions are connected to suitable binding posts I and K As shown, the electrodes I and K are in the form of parallel plate-like bodies, and the shape and effective length of the flow path between them is varied by means of a barrier L of insulating material which is movable in a plane between and parallel to the electrodes. by means of a thermostat shown as a Briquet spiral F supported from the plug H by means of a post G, as the spiral F is supported from the insulation body E in Fig. 2. With the arrangement shown in Figs. 3 and 4 when the temperature of the fluid with which the electrodes I and K are in contact increases. the barrier Lis moved toward a position in which it extends directly between the electrodes I and K and correspondingly elongates and changes the shape of the path of electric flow between them, and as the temperature of the fluids decreases it is moved away from this position so that the conductivity of the flow path between the electrodes I and K is maintained constant notwithstanding variations in the temperature of the fluid material forming the path.
It willbe apparent to those skilled in the art that the provisions illustrated and described form simple and eiiective means for accomplishing their intended purpose of maintaining a resistance of the electric flow path between the electrodes, which does not vary with the temperature of the fluid forming the path. By proceeding in accordance with the present invention it is possible to make each of a group of conductivity measuring electrode arrangements, self compensating so that they may all be used in conjunction with an ordinary measuring instrument without other compensating provisions to give conductivity measurements which are unafl'ected by the temperature of the fluids in contact with the electrodes. While in accord-' ance with the provisions of the statutes I have illustrated and described the best forms of my invention now known to me it will be apparent to those skilled in the art that other forms of construction and arrangement-may be employed without departing from the spirit of my invention as set forth in the appended claims. a
Having now described my invention, what I claim as new and desire to obtain by Letters Patent, is:
1. A device for measuring the electric conductivity of a fluid having electrodes immersed in said fluid, an obstruction movable to vary'the path of electrical flow between said electrodes, and thermally responsive means in the fluid for operating the obstruction in accordance with temperature changes of the fluid.
2. A device for measuring the electrical' Oct. A. D. 1923.
EARL A. KEELER.
US670143A 1923-10-22 1923-10-22 Measuring electric conductivity of fluid Expired - Lifetime US1826886A (en)

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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2422873A (en) * 1943-05-19 1947-06-24 Photoswitch Inc Electrical conductivity cell
US2540425A (en) * 1948-02-20 1951-02-06 Paul F Byrum Antifreeze indicator
US2769140A (en) * 1952-03-26 1956-10-30 West Virginia Pulp & Paper Co Means for measuring electrical conductivity of liquids
US3114257A (en) * 1959-03-09 1963-12-17 Western Electric Co Apparatus for sensing the flow of a substance through a liquid medium
US3784453A (en) * 1970-12-16 1974-01-08 H Dworkin Process and apparatus for making radioactive labeled protein material

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2422873A (en) * 1943-05-19 1947-06-24 Photoswitch Inc Electrical conductivity cell
US2540425A (en) * 1948-02-20 1951-02-06 Paul F Byrum Antifreeze indicator
US2769140A (en) * 1952-03-26 1956-10-30 West Virginia Pulp & Paper Co Means for measuring electrical conductivity of liquids
US3114257A (en) * 1959-03-09 1963-12-17 Western Electric Co Apparatus for sensing the flow of a substance through a liquid medium
US3784453A (en) * 1970-12-16 1974-01-08 H Dworkin Process and apparatus for making radioactive labeled protein material

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